Spray tip and method of manufacture

ABSTRACT

A spray tip comprises a tip body, a tip piece, and a pre-orifice piece. The tip body has a fluid channel along a channel axis (AC). The tip piece is disposed within the fluid channel, and has a stepped, narrowing passage that terminates in an outlet orifice. The pre-orifice piece has an inlet passage, and is disposed within the fluid channel, abutting and immediately upstream of the tip piece. The pre-orifice piece and the tip piece together define a turbulating chamber therebetween.

CROSS-REFERENCE TO RELATED APPLICATION(S)

This application is a continuation of U.S. application Ser. No.16/735,144 filed Jan. 6, 2020 for “Spray Tip and Method of Manufacture”by S. Becker, D. Olson, C. Wojciechowski, and D. Thompson, which is acontinuation of U.S. application Ser. No. 15/022,044 filed Mar. 15, 2016for “Spray Tip and Method of Manufacture” by S. Becker, D. Olson, C.Wojciechowski, D. Thompson, which in turn claims the benefit of PCTApplication No. PCT/US2014/055804 filed Sep. 16, 2014, which in turnsclaims the benefit of U.S. Provisional Application Nos. 61/878,191 filedSep. 16, 2013; 61/929,403 filed Jan. 20, 2014; and 61/987,654 filed May2, 2014.

BACKGROUND

The present invention relates generally to fluid spraying systems. Moreparticularly, the invention relates to a spray tip used to define aspray pattern at a sprayer nozzle, and a method for making the spraytip.

Fluid spraying systems are commonly used in a wide variety ofapplications, from industrial assembly to home painting. Handheldsprayers can be used by a human operator, while automated sprayers aretypically used in mechanized manufacturing processes. Fluid sprayed bysuch systems conforms to a spray pattern defined, in large part, byaperture shape and size. In some cases, spray patterns may exhibitnon-uniformity in the form of fringes or tails where more spray fluid isdeposited, typically at or near the edges of spray patterns. Suchdefects can often be reduced or eliminated by increasing spray pressure,at the cost of requiring increased power and more structurally solidcomponents, and producing overspray (undesirable fine spray particlesthat do not land on the desired substrate to be coated).

SUMMARY

In a first embodiment, a spray tip comprises a tip body, a tip piece,and a pre-orifice piece. The tip body has a fluid channel along achannel axis. The tip piece is disposed within the fluid channel, andhas a stepped, narrowing passage that terminates in an outlet orifice.The pre-orifice piece has an inlet passage, and is disposed within thefluid channel, abutting and immediately upstream of the tip piece. Thepre-orifice piece and the tip piece together define a turbulatingchamber therebetween.

In a second embodiment, a spray device includes a pressurized source ofspray fluid, a nozzle disposed to spray the spray fluid, and a spray tipdisposed in the nozzle to define a spray pattern. The spray tip includesa tip piece with an outlet aperture, a pre-orifice piece with an inletaperture, and a tip body injection-molded about the tip piece and thepre-orifice piece. The pre-orifice piece is disposed upstream of the tippiece, and the tip body has a fluid channel disposed to carry the sprayfluid to the pre-orifice piece.

In a third embodiment, a method of manufacture for a spray tip includesfabricating a tip piece with an outlet orifice, fabricating apre-orifice piece with an inlet orifice, clamping the tip piece and thepre-orifice piece together in an engaged position, and injection-moldinga tip body about the tip piece and the pre-orifice piece, such that thetip body includes a fluid channel to the inlet orifice along a channelaxis, and an outlet opening at the outlet orifice along the channelaxis.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of fluid sprayer.

FIG. 2 is a cross-sectional perspective view of a fluid spray tip.

FIGS. 3a, 3b, and 3c are cross-sectional views of different embodimentsof a tip piece of the fluid spray tip.

FIG. 4 is a method flowchart illustrating a method of manufacture of thefluid spray tip.

FIG. 5 is a cross-sectional view of the fluid spray tip, during assemblyaccording to the method of FIG. 4.

While the above-identified drawing figures set forth several embodimentsof the invention, other embodiments are also contemplated, as noted inthe discussion. In all cases, this disclosure presents the invention byway of representation and not limitation. It should be understood thatnumerous other modifications and embodiments can be devised by thoseskilled in the art, which fall within the scope and spirit of theprinciples of the invention. The figures may not be drawn to scale.

DETAILED DESCRIPTION

The present invention relates to a spray tip with a turbulating tippiece and pre-orifice piece locked within an overmolded tip body. Thetip piece and pre-orifice piece cooperate to form a turbulating chambertherebetween, and the tip piece includes a turbulating stepped patternconverging towards an outlet aperture. The overmolded tip body capturesthe tip piece and pre-orifice piece without the need for additionalretainers or anchoring parts or seals.

FIG. 1 is a perspective view of sprayer 10, a handheld fluid sprayeraccording to one embodiment of the present invention. Sprayer 10includes body 12, source 14, grip 16, trigger 18, nozzle 20, spray tips22 (with outlet aperture 24) and 22′, guard 26, prime valve 28, base 30,power cord 32, and storage slot 34. In the depicted embodiment, sprayer10 can, for example, be an electrical spray device for use with paint,solvent, or other fluids. Although sprayer 10 is illustrated as ahand-held device, stationary or machine-driven sprayers can also utilizethe spray tip of the present invention.

Body 12 of sprayer 10 includes pumping elements suitable to drive fluidfrom source 14 towards nozzle 20, and expel fluid from outlet aperture24 of spray tip 22. In the depicted embodiment, body 12 can, forexample, include electric motorized pumping elements that receive powerthrough power cord 32. In alternative embodiments, body 12 can includepumps powered by a battery (not shown). Grip 16 provides a hand-hold fora human user. When the user depresses trigger 18, sprayer 10 draws fluidfrom source 14 through body 12, and expels this fluid through nozzle 20.Trigger 18 can, for example, actuate electric or pneumatic pumps withinbody 12. Although source 14 is depicted as a substantially cylindricalfluid receptacle carried by body 12, alternative embodiments of source14 can include receptacles of other shapes and sizes, as well as fluidlines or hoses connectable to external fluid supplies. Source 14 can,for example, be a disposable paint container such as a deflating bag.Prime valve 28 can be used to prime pumping elements within body 12prior to spraying fluid from source 14.

Nozzle 20 houses spray tip 22. Spray tip 22 can, for example, be aremovable element with a substantially cylindrical portion insertableinto nozzle 20 to provide a desired spray pattern, as depicted anddescribed in further detail below with respect to FIG. 2. Spray tip 22includes outlet aperture 24, a ground or otherwise machined narrowaperture that atomizes spray fluid and defines a spray pattern. Sprayer10 can accept various spray tips 22, e.g. spray tips 22 and 22′ withdifferent outlet apertures 24 capable of producing different spraypatterns suitable for different applications. For example, a spray tip22 that produces a wide spray pattern can be swapped out for a spray tip22′ that produces a narrow spray pattern when precision spraying isrequired. In the depicted embodiment, base 30 provides attachment pointfor power cord 32, and houses storage slot 34 for one such reserve oralternate spray tip 22′. Nozzle 20 is protected by guard 26, a rigid orsemi-rigid positioning element. In the depicted embodiment, guard 26 isan elliptical frame situated forward of spray tip 22.

FIG. 2 a cross-sectional perspective view of spray tip 22. Spray tip 22includes tip body 100, tip piece 102, and pre-orifice piece 104. Tippiece 102 and pre-orifice piece 104 include chamber surfaces 108 and110, respectively, which collectively define turbulating chamber 106.Tip piece 102 further includes outlet aperture 24, as described above,and pre-orifice piece 104 further includes lip 111 and inlet passage112. Tip body 100 includes fluid channel 114 disposed along channel axisA_(C), outlet opening 116 also disposed along channel axis A_(C), rearblock 118, front block 120, bayonet 121, and tab 122.

Outlet aperture 24 has grind angle φ, and produces spray pattern S. Asdescribed above with respect to FIG. 1, spray tip 22 can, for example,be a removable component that can be swapped out depending on desiredspray pattern. To this end, tab 122 provides a grip point to facilitateinserting spray tip 22 into nozzle 20 (see FIG. 1). In some embodiments,tab 122 can facilitate twisting or locking spray tip 22 into place withbayonet 121, which can for example engage internal grooves (not shown)of guard 26.

In the illustrated embodiment, tip body 100 defines fluid channel 114,an axial passage oriented along channel axis A_(C). Fluid channel 114carries working fluid from source 14 to pre-orifice piece 104. Chambersurfaces 108 and 110 of tip piece 102 and pre-orifice piece 104,respectively, define boundaries of turbulating chamber 106. Chambersurface 108 is an upstream surface of tip piece 102, while chambersurface 110 is a downstream surface of pre-orifice piece 104. Fluid fromfluid channel 114 enters turbulating chamber 108 through inlet passage112 of pre-orifice piece. In the depicted embodiment, chamber surfaces108 and 110 are both substantially conical or frustoconical in shape,and narrow in opposite directions, and turbulating chamber 108 isaccordingly a double-conical cavity situated between tip piece 102 andpre-orifice piece 104. In the depicted embodiment, pre-orifice piece 104includes lip 111, an annular ridge that directs fluid flow along chambersurface 110 and aligns pre-orifice piece 104 with tip piece 102 duringassembly.

Inlet passage 112 is a narrow opening or aperture in pre-orifice piece104 that constricts flow. Inlet passage 112 and turbulating chamber 108increase working fluid turbulence, reducing net pressure losses acrossoutlet aperture 24 and thereby improving the uniformity of spray patternS. In some embodiments, this increased working fluid turbulence canfacilitate reducing or eliminating undesirable “tails” (highconcentration fringes) in spray pattern S. Reduced pressure loss acrossoutlet aperture 24 also allows sprayer 10 to function at lowerpressures, reducing power and structural requirements. In someembodiments tip piece 102 can include further turbulating features, asdescribed in greater detail below with respect to FIGS. 3a, 3b , and 3c.

Tip piece 102 and pre-orifice piece 104 are held securely along chamberaxis A_(C) within tip body 100. Tip body includes rear block 118 andfront block 120 disposed axially upstream and downstream, respectively,of pre-orifice piece 104 and tip piece 102. Rear block 118 and frontblock 120 capture tip piece 102 and pre-orifice piece 104 axially,preventing tip piece 102 and/or pre-orifice piece 104 from escaping tipbody 100, e.g. under spray pressure. Rear block 118 and front block 120can, for example, be formed when tip body 100 is injection molded (seeFIGS. 4 and 5, and accompanying description) by overmolding tip body 100about tip piece 102 and pre-orifice piece 104, thereby creating a fitthat restrains axial (forward or aft) and radial movement relative totip body 100. In at least some embodiments, tip body 100 directlycontacts tip piece 102 and pre-orifice piece 104 with no interveningelements.

Outlet aperture 24 of tip piece 102 defines spray pattern S with sprayangle φ. Tip body 100 includes outlet opening 116 about outlet aperture24, sized to prevent fouling and avoid obstructing spray pattern S byleaving tip piece 102 exposed around outlet aperture 24.

FIGS. 3a, 3b, and 3c are cross-sectional views of three further (oralternative) embodiments of tip piece 102, labeled tip pieces 102 a, 102b, and 102 c, respectively. All three tip piece embodiments includeoutlet aperture 24 with grind angle y suited to produce spray pattern S.Outlet aperture 24 can, for example, be a diverging opening such as aground wedge or angle cut into a downstream wall of tip pieces 102 a,102 b, and 102 c. All three tip piece embodiments also include some formof turbulating chamber 106, chamber surface 108, and outlet passage 124.

Tip piece 102 a of FIG. 3a illustrates outlet passage 124 a, which iscomprised of a plurality of cylindrical sections 126 with steps 128converging (i.e. decreasing in diameter) from turbulating chamber 106 ato outlet orifice 24. Turbulating chamber 106 a has conical orfrustoconical walls with chamber surface 108 a, as described above withrespect to FIG. 2. Cylindrical sections 126 and steps 128 furtherturbulate fluid flow from turbulating chamber 106 to outlet aperture,reducing pressure loss across outlet orifice 24.

Tip piece 102 b of FIG. 3b illustrates outlet passage 124 b, asubstantially cylindrical channel extending from turbulating chamber 106b to outlet orifice 24. Turbulating chamber 106 b is a substantiallycylindrical cavity, chamber surface 108 b is a substantially annularwall concentrically disposed about channel axis A_(C).

Tip piece 102c of FIG. 3c illustrates outlet passage 124 c andturbulating chamber 106 c. Like outlet passage 124 b, outlet passage 124c is a substantially cylindrical channel extending from turbulatingchamber 106 c to outlet orifice 24. Turbulating chamber 106 c is aflared cavity with annular recess 130 to promote fluid turbulence.Although not shown in FIG. 3b or 3 c, some embodiments of tip piece 102including a substantially cylindrical turbulating chamber 106 caninclude a stepped outlet passage 124, as illustrated in FIG. 3 a.

All illustrated embodiments of tip piece 102 (including tip pieces 102a, 102 b, and 102 c) include a chamber surface 108 that forms one sideof turbulating chamber 106. Turbulating chamber 106, outlet passage 124,and the step interface therebetween all promote fluid turbulence,thereby reducing undesirable pressure loss across outlet orifice 24.

FIG. 4 is a flowchart illustrating method 200 for of manufacture forspray tip 22. FIG. 5 is a cross-sectional view of spray tip 100 takenalong section line 5-5 of FIG. 2 during manufacture according to method200. FIG. 5 depicts tip body 100, tip piece 102, and pre-orifice piece104 of spray tip 22, including outlet opening 116 for outlet orifice 24,and channel 115 to pre-orifice piece 102. FIG. 5 further depicts variousmanufacturing tools (not shown in FIG. 2), including clamp assembly 300(with clamp pin 302, clamp tube 304, aperture clamp 306, and biasingsprings 308 and 310) and injection mold 312 (with mold sections 314 and316).

According to method 200, tip piece 102 and pre-orifice piece 104 arefirst fabricated. (Steps S1 and S2, respectively). Tip piece 102 andpre-orifice piece 104 can, for example, be formed of tungsten carbide orsimilar rigid, powder-based materials. Tip piece 102 and pre-orificepiece 104 can, for example, be cast into a desired shape and ground orotherwise machined to produce outlet aperture 24.

Next, tip piece 102 and pre-orifice piece 104 are clamped together in anengaged position with clamp assembly 300. (Step S3). In the illustratedembodiment of FIG. 5, clamp pin 302 secures pre-orifice piece 104 from adownstream direction, while clamp tube 304 and aperture clamp 306 securetip piece 102 from an upstream direction. Clamp pin 302 can be asubstantially cylindrical rod biased against pre-orifice piece 104 bybiasing spring 308. Clamp pin 302 includes retainer 303, an axialprotrusion that fits inside inlet passage 102, allowing clamp pin 302 toposition pre-orifice piece 104 laterally as well as axially in alignmentwith tip piece 102, along channel axis A_(C). Clamp tube 304 similarlysituates and retains tip piece 102 against pre-orifice piece 104, whileaperture clamp 306 is biased against tip piece 102 by biasing spring 310to seal or cover outlet aperture 24 against fluid ingress duringmanufacture. Alternative configurations of tip piece 102 andpre-aperture blank 104 can necessitate different clamping arrangementsfor clamp assembly 300.

Once tip piece 102 and pre-orifice piece 104 are clamped in place,injection mold 312 is assembled about tip piece 102 and pre-orificepiece 104. (Step S4). In the depicted embodiment, injection mold 312 isa two-part mold comprising mold sections 314 and 316. Mold sections 314and 316 can, for example, be halves of injection mold 312 split alongparting line P. In alternative embodiments, injection mold 312 cancomprise three or more distinct sections. Once mold sections 314 and 316are in place, polymer is injected into injection mold 312 to form tipbody 100 about blanks 102 and 104, thereby retaining blanks 102 and 104within tip body 100. (Step S5). In the depicted embodiment, fluidchannel 114 is defined within tip body by clamp pin 302, and outletopening 116 is defined by clamp tube 304. Once tip body 100 hashardened, injection mold 312 is removed, clamping assembly 300 isreleased, and spray tip 22 is removed from molding tooling. (Step S6).The finished spray tip 22 is then ready for use.

Method 200 provides an inexpensive means of fabricating spray tip 22 byovermolding tip body 100 around tip piece 102 and pre-orifice piece 104.The overmolding of tip body 100 captures blanks 102 and 104 without needfor additional retainers or anchoring elements. Tip piece 102 andpre-orifice piece 104 together reduce pressure loss across outletaperture 24, improving the uniformity of spray pattern S and reducingpower and structural requirements of sprayer 10.

Discussion of Possible Embodiments

The following are non-exclusive descriptions of possible embodiments ofthe present invention.

A spray tip comprising: a tip body with a fluid channel along a channelaxis; a tip piece disposed within the fluid channel, and having astepped, narrowing passage that terminates in an outlet orifice; apre-orifice piece having an inlet passage, the pre-orifice piecedisposed within the fluid channel, abutting and immediately upstream ofthe tip piece, so as to define a turbulating chamber between the tippiece and the pre-orifice piece.

The spray tip of the preceding paragraph can optionally include,additionally and/or alternatively, any one or more of the followingfeatures, configurations and/or additional components:

A further embodiment of the foregoing spray tip, wherein the turbulatingchamber is a double-conical chamber formed between a first conicalsurface of the pre-orifice piece and a second conical surface of the tippiece.

A further embodiment of the foregoing spray tip, wherein the pre-orificepiece includes an annular lip that engages with the first conicalsurface.

A further embodiment of the foregoing spray tip, wherein the inletpassage and the second conical surface are disposed coaxially about thechannel axis.

A further embodiment of the foregoing spray tip, wherein the stepped,narrowing passage comprises a plurality of sequential cylindrical stepsdisposed coaxially with the channel axis, arranged converging fromwidest to narrowest at the outlet orifice.

A further embodiment of the foregoing spray tip, wherein the tip body isformed of polymer.

A further embodiment of the foregoing spray tip, wherein the tip pieceand the pre-orifice piece are captured along the channel axis on bothsides within a cavity of the tip body.

A spray device comprising: a pressurized source of spray fluid; a nozzledisposed to spray the spray fluid; and a spray tip disposed in thenozzle to define a spray pattern, the spray tip comprising: a tip piecewith an outlet aperture; a tip body injection-molded about the tippiece, and having a fluid channel disposed to carry the spray fluid tothe tip piece

The spray device of the preceding paragraph can optionally include,additionally and/or alternatively, any one or more of the followingfeatures, configurations and/or additional components:

A further embodiment of the foregoing spray device, wherein the spraytip further comprises a pre-orifice piece disposed upstream of the tippiece, with an inlet aperture disposed to receive fluid from the fluidchannel.

A further embodiment of the foregoing spray device, wherein the tippiece and the pre-orifice piece cooperate to form a turbulating chambertherebetween.

A further embodiment of the foregoing spray device, wherein theturbulating chamber has a double-conical shape formed between a firstconical surface of the tip piece and a second conical surface of thepre-orifice piece.

A further embodiment of the foregoing spray device, wherein the tippiece has a stepped passage that narrows from the turbulating chamber tothe outlet aperture.

A further embodiment of the foregoing spray device, wherein the outletaperture defines a spray pattern.

A spray tip comprising: a tip body with a fluid channel along a channelaxis; and a tip piece disposed within the fluid channel, and having astepped, narrowing outlet passage comprising a plurality of sequentialcylindrical steps disposed coaxially with the channel axis, arrangedconverging from widest at an upstream end to narrowest at an outletorifice.

The spray tip of the preceding paragraph can optionally include,additionally and/or alternatively, any one or more of the followingfeatures, configurations and/or additional components:

A further embodiment of the foregoing spray tip, wherein the tip pieceis formed of tungsten carbide.

A further embodiment of the foregoing spray tip, further comprising apre-orifice piece disposed upstream of the tip piece, with an inletaperture disposed to receive fluid from the fluid channel.

A further embodiment of the foregoing spray tip, wherein the tip pieceand the pre-orifice piece cooperate to form a turbulating chambertherebetween.

A method of manufacture for a spray tip, the method comprising:fabricating a tip piece with an outlet orifice; fabricating apre-orifice piece with an inlet orifice; clamping the tip piece and thepre-orifice piece together in an engaged position; injection-molding atip body about the tip piece, such that the tip body includes a fluidchannel to the inlet orifice along a channel axis, and an outlet openingat the outlet orifice along the channel axis

The method of the preceding paragraph can optionally include,additionally and/or alternatively, any one or more of the followingfeatures, configurations and/or additional components:

A further embodiment of the foregoing method, wherein injection-moldingthe tip body comprises overmolding the tip body about the clamped tippiece and pre-orifice piece such that the tip body restrains the tippiece and pre-orifice piece against movement within the tip body.

A further embodiment of the foregoing method, further comprisingunclamping the tip piece and the pre-orifice piece afterinjection-molding the tip body.

A further embodiment of the foregoing method, wherein clamping the tippiece and the pre-orifice piece together in an engaged position involvessecuring and aligning the pre-orifice piece along the channel axis witha clamp pin, and securing and aligning the tip piece along the channelaxis with a clamp tube.

A further embodiment of the foregoing method, wherein the clamp pindefines the fluid channel for the injection molding, and the clamp tubedefines the outlet opening for the injection molding.

A further embodiment of the foregoing method, wherein fabricating atleast one of the tip piece and the pre-orifice piece comprises grindingtungsten carbide base material.

Summation

Any relative terms or terms of degree used herein, such as“substantially”, “essentially”, “generally”, “approximately” and thelike, should be interpreted in accordance with and subject to anyapplicable definitions or limits expressly stated herein. In allinstances, any relative terms or terms of degree used herein should beinterpreted to broadly encompass any relevant disclosed embodiments aswell as such ranges or variations as would be understood by a person ofordinary skill in the art in view of the entirety of the presentdisclosure, such as to encompass ordinary manufacturing tolerancevariations, incidental alignment variations, alignment or shapevariations induced by thermal, rotational or vibrational operationalconditions, and the like.

While the invention has been described with reference to an exemplaryembodiment(s), it will be understood by those skilled in the art thatvarious changes may be made and equivalents may be substituted forelements thereof without departing from the scope of the invention. Inaddition, many modifications may be made to adapt a particular situationor material to the teachings of the invention without departing from theessential scope thereof. Therefore, it is intended that the inventionnot be limited to the particular embodiment(s) disclosed, but that theinvention will include all embodiments falling within the scope of theappended claims.

1. A spray tip comprising: a tip body having a cylindrical portion anddefining a fluid channel along a channel axis that extends transverselythrough the cylindrical portion; a tip piece located within thecylindrical portion, the tip piece having an outlet passage disposedalong the channel axis, the outlet passage having an outlet orificeconfigured to define a spray pattern of atomized fluid, the tip pieceincluding a plurality of annular steps along the channel axis thatsuccessively narrow the fluid channel toward the outlet orifice; and apre-orifice piece located within the cylindrical portion, thepre-orifice piece having an inlet passage disposed on the channel axisupstream of the tip piece; wherein: the tip piece and the pre-orificepiece together form a turbulating chamber situated along the channelaxis and between the inlet passage and the outlet orifice, theturbulating chamber wider in diameter than each of the inlet passage andthe outlet passage.
 2. The spray tip of claim 1, wherein the tip bodycomprises a polymer material.
 3. The spray tip of claim 1, wherein thetip piece and the pre-orifice piece together form a multi-piece assemblysituated along the channel axis.
 4. The spray tip of claim 3, whereinthe multi-piece assembly is axially captured by the tip body.
 5. Thespray tip of claim 3, wherein the multi-piece assembly iscircumferentially surrounded and in contact with the tip body, such thatthe tip body the holds the multi-piece assembly within the channel. 6.The spray tip of claim 3, wherein the multi-piece assembly has anoutermost assembly diameter greater than both the upstream channeldiameter and the downstream channel diameter.
 7. The spray tip of claim1, wherein the plurality of annular steps are disposed coaxially withthe channel axis.
 8. The spray tip of claim 1, wherein the tip bodyabuts and contacts radially outer surfaces of the tip piece and thepre-orifice piece.
 9. The spray tip of claim 1, wherein at least one ofthe tip piece and the pre-orifice piece is formed of tungsten carbide.10. The spray tip of claim 1, further comprising an annular lipprojection that forms part of the turbulating chamber.
 11. The spray tipof claim 10, wherein the annular lip projection extends from one of thetip piece or the pre-orifice piece and is received within the other ofthe tip piece or the pre-orifice piece.
 12. The spray tip of claim 10,wherein the annular lip projection extends from the pre-orifice pieceand is received within the tip piece.
 13. The spray tip of claim 10,wherein the annular lip projection aligns the pre-orifice piece with thetip piece.
 14. The spray tip of claim 10, wherein the annular lipprojection directs fluid flow along a surface of the turbulatingchamber.